JP4481158B2 - Optical terminal device - Google Patents

Description

The present invention relates to an optical terminal device having a power backup mechanism and a photoelectric conversion element that enable reception of a predetermined sound notification broadcast transmitted optically even when a commercial power supply fails.
The present invention relates to an optical terminal device (V-ONU: video-based optical subscriber line termination device) capable of receiving a voice notification broadcast or the like for notifying local disaster-related information through an optical communication network. .

  There is known a CATV system in which a television broadcast and an FM notification (76-90 MHz band) audio notification broadcast are multiplexed using a coaxial cable. In this case, even if the commercial power supply fails, the power supply is supplied through the coaxial cable core of the outdoor transmission line by the power failure backup device of the CATV transmission line. It operates and RF signals are transmitted to each home. Therefore, by receiving this signal with a battery-powered FM notification broadcast terminal, FM radio, or the like, the voice notification broadcast can be heard in each home even during a power failure.

  On the other hand, recently, FTTH (: Fiber to the Home) system in which an optical fiber cable is connected is spreading to homes. This system is mainly used for communication, but it is also considered to handle a wideband signal such as a multiplexed television signal. In such a system, it is considered to multiplex voice notification broadcasts transmitted from local governments in the FM band for emergency notifications and disasters, or for normal information transmission.

However, in the FTTH system, an optical terminal device that converts an optical signal into an electrical signal is required in each household in front of the FM notification broadcasting terminal and FM radio. Since the power supply to this optical terminal device is performed from the outlet of each household, when the commercial power supply fails, this optical terminal device does not operate, and audio notification broadcasting is performed from the FM notification broadcasting terminal or FM radio of each home. There is a problem that you cannot hear.
In addition, it may be possible to simply supply power to the device with an auxiliary power source such as a battery. However, since this is a power supply to an amplifier that amplifies a wide band of 90 to 2000 MHz, a large amount of power must be supplied and power can be supplied. Time is remarkably shortened and urgent voice announcement broadcasting cannot be received for a long time. For this reason, there is a problem that voice notification broadcasts cannot be received even when necessary in the event of a disaster such as an earthquake, flood, landslide, or typhoon.

  The present invention has been made to solve the above-described problems. The purpose of the present invention is to enable reception of an audio notification broadcast during a power failure in a broadband television transmission system using an optical transmission line. This is to increase the reception time.

In order to solve the above problems, the following means are effective.
In other words, the first means of the present invention multiplexes a multiplexed broadband television signal and a narrow band audio announcement broadcast signal that is lower than the bandwidth of the broadband television signal, and performs optical transmission. Installed in each terminal of a system distributed to each terminal by a route, converts an optical signal into an electrical signal, amplifies it, and supplies DC power converted from commercial power in an optical terminal device that supplies the output device Connected between the power supply terminal, the power supply terminal and the ground, and connected to the photoelectric conversion element so as to supply direct current power to the photoelectric conversion element when the commercial power supply is interrupted. and a backup power supply device, is connected to one terminal of the photoelectric conversion element, the entire band electric signal converted by the photoelectric conversion element amplifies, feeding terminal connected to the power supply terminal, the power supply of the commercial power supply A first radio frequency amplifier circuit which operates Te is connected to the other terminal of the photoelectric conversion elements, out of the converted electrical signals by the photoelectric conversion element is amplified narrowband signal including a bandwidth of the audio announcement broadcast signal output And a second high-frequency amplifier circuit that operates by being supplied with power from the backup power supply device and having a power supply terminal connected to the backup power supply device . The second high-frequency amplifier circuit includes a transistor that amplifies the signal, A bias circuit, and the bias circuit applies a voltage to the base / gate of the transistor by a voltage from the backup power supply, and supplies a voltage to the emitter / source of the transistor by a voltage from the power supply terminal. During the power outage, the transistor base / gate and emitter / source bias voltages should be higher than the threshold voltage. Period during which the power supply from the source is characterized by having to be a circuit to be smaller than the threshold voltage.

Here, the audio notification broadcast is generally an audio broadcast using an FM band of 76 to 90 MHz. This audio notification broadcast can be received by an FM notification broadcast terminal, FM radio, or the like. However, in the present invention, a band that is lower than a broadband television signal band and can be received by a battery-powered radio installed in a general household is particularly limited to the 76 to 90 MHz band. is not.
The narrow band means that it is narrower than the band of the multiplexed broadband television signal, and does not necessarily mean the band of 1FM broadcasting station. Normally, a part of the 76 to 90 MHz band is used, but the second high-frequency amplifier circuit has a part of this band, the entire band of 76 to 90 MHz, or a narrow band including the 76 to 90 MHz band. A circuit to amplify.

On the other hand, the first high-frequency amplifier circuit that operates when the commercial power supply is normal amplifies the signal of the entire band to be received by each home, and naturally, the band of the voice notification broadcast is also amplified. To do. Therefore, if the commercial power supply is normal, the voice notification broadcast is amplified by the first high-frequency amplifier circuit and output to a radio or the like.
On the other hand, at the time of a power failure of the commercial power supply, only the audio notification broadcast is amplified by the second high-frequency amplifier circuit fed by the backup power supply and output to a battery-powered radio or the like to listen to the audio notification broadcast in each home Can do.

According to a second means of the present invention, in the first means, the photoelectric conversion element is provided by a photodiode, and a high-frequency signal input terminal of the second high-frequency amplifier circuit is used as a cathode of the photoelectric conversion element. And the input terminal of the high frequency signal of the first high frequency amplifier circuit is connected to the anode of the photoelectric conversion element.
However, the form in which the high-frequency signal input terminal of the second high-frequency amplifier circuit is connected to the cathode of the photoelectric conversion element may be indirect, for example, a buffer resistor or the like may be interposed there. Alternatively, such a buffer resistor may be considered as a part (previous stage) of the second high-frequency amplifier circuit.

  According to a third means of the present invention, in the first or second means described above, the backup power supply device is constituted by a large-capacity capacitor that is charged by power supply from a commercial power supply.

  According to a fourth means of the present invention, in the third means described above, the backup power supply apparatus is provided with a current limiting circuit for making the power supply current to the second high-frequency amplifier circuit constant at a small current. .

According to a fifth means of the present invention, in any one of the first to fourth means, an input terminal for inputting an output signal of the first high frequency amplifier circuit and an output of the second high frequency amplifier circuit. A directional coupler including an isolation terminal for inputting a signal and having a branch terminal as a monitor terminal for a broadband television signal.

According to a sixth means of the present invention, there is provided the filter according to any one of the first to fifth means, wherein a narrow band signal including a voice notification broadcast band is passed to an input stage of the second high frequency amplifier circuit. It is to provide.

According to a seventh aspect of the present invention, a multiplexed wide-band television signal and a narrow-band audio notification broadcast signal that is lower than the wide-band television signal are multiplexed and optical transmission is performed. Installed in each terminal of a system distributed to each terminal by a route, converts an optical signal into an electrical signal, amplifies it, and supplies DC power converted from commercial power in an optical terminal device that supplies the output device Connected between the power supply terminal, the power supply terminal and the ground, and connected to the photoelectric conversion element so as to supply direct current power to the photoelectric conversion element when the commercial power supply is interrupted. and a backup power supply device, is connected to one terminal of the photoelectric conversion element, the entire band electric signal converted by the photoelectric conversion element amplifies, feeding terminal connected to the power supply terminal, the power supply of the commercial power supply A high frequency amplifier circuit which operates Te, is connected between the power supply terminal of the backup power supply and the high frequency amplifying circuit, a current limiting circuit comprising a constant current diode for supplying a constant current direction from the backup power supply to the high frequency amplifier circuit It is characterized by having.
By the above means of the present invention, the above-mentioned problem can be effectively or rationally solved.

The effects obtained by the above-described means of the present invention are as follows.
In an amplifying circuit using a transistor, generally, the GB product decreases when the current becomes low, and the gain decreases as the frequency increases, as exemplified in FIGS. For this reason, in an amplifier circuit using a transistor, generally, a higher power is required to obtain a desired gain as the frequency becomes higher. For example, in order to amplify a multiplexed broadband television signal, power that is approximately 100 times the power used when amplifying an FM voice notification broadcast is required.

However, since the audio notification broadcast band is generally set to a frequency band lower than the multiplexed broadband television signal band, according to the first means of the present invention, only the signal of the lower frequency band is amplified. The second high-frequency amplifier circuit can operate sufficiently even when the power supply voltage decreases. This means that the optical terminal device according to the present invention, which supports only a low frequency band such as a voice notification broadcast, can operate for a longer time when a power failure occurs due to a decrease in power supply voltage due to the discharge of the backup power supply device.
Further, according to the present invention, the transistor of the second high-frequency amplifier circuit is not operated when the commercial power supply is normal, and the transistor can be made operable only during a power failure. Therefore, when the commercial power supply is normal, it is possible to eliminate the influence on the broadband television signal and the audio notification broadcast.

Further, according to the second means of the present invention, since the signal input terminal of the second high-frequency amplifier circuit is connected to the cathode of the photodiode, the reflection from the second high-frequency amplifier circuit system that does not operate when the power supply is normal. The signal is prevented from entering the first high-frequency amplifier circuit that operates when the power supply is normal. As a result, it is possible to prevent signal deterioration due to the connection of the second high-frequency amplifier circuit system in the amplification of the television signal and the amplification of the audio notification broadcast when the power supply is normal.
That is, with such a configuration, when the power supply is normal, the influence of the reflection from the second high-frequency amplifier circuit system that does not amplify the audio notification broadcast band on the first amplifier circuit that amplifies the signal in the entire band is eliminated. be able to.

  Further, according to the third means of the present invention, since the backup power supply device is configured using a large-capacity capacitor, it is possible to greatly reduce the operation cost such as periodic battery replacement by the end user. it can.

  Further, the discharge characteristic of the capacitor has an attenuation characteristic determined by a time constant. On the other hand, since the second high-frequency amplifier circuit only amplifies narrow-band signals including a voice announcement release band that is lower than the multiplexed broadband television signal band, the gain of this band can be maintained even if the power supply voltage decreases. It does not decrease greatly. Therefore, it is possible to withstand long-time power supply by suppressing the discharge of the cupacitator by limiting the power supply current by lowering the power supply voltage from the beginning of the power outage. Thus, according to the fourth means of the present invention, a longer backup time can be secured.

According to the fifth means of the present invention, the output of the first high-frequency amplifier circuit and the output of the second high-frequency amplifier circuit are synthesized using the directionality of the directional coupler. Since the output of the second high-frequency amplifier circuit is connected to the isolation terminal of the directional coupler, when the power supply is normal, the signal output from the first high-frequency amplifier circuit is the second high-frequency amplifier circuit side. On the contrary, when the power supply fails, the audio notification broadcast signal output from the second high-frequency amplifier circuit is prevented from entering the output of the first high-frequency amplifier circuit. As a result, signal loss and reflection are suppressed, so that even if the second high-frequency amplifier circuit is provided, the signal quality is not deteriorated. The branch terminal of the directional coupler can be a terminal for monitoring a broadband television signal.

In addition, according to the sixth means of the present invention, since the received signal input to the second high frequency amplifier circuit can be limited to the audio notification broadcast band, interference from signals in other bands can be prevented. It is possible to maintain a high quality of the voice announcement broadcast at the time of power failure.

According to the seventh means of the present invention, even in an optical terminal device that does not have the second high-frequency amplifier circuit as described above, the voice notification broadcast is amplified for a long time by the current limiting circuit in the event of a power failure. can do. If the power supply current is limited and the power supply voltage is reduced from the beginning of the power failure, the broadband television signal cannot be amplified, but the multiplexed broadband television signal can be sufficiently amplified. In other words, it is possible to amplify the voice announcement broadcast over a long period of time at the time of a power failure.

  Note that any of the above current limiting circuits can be configured using a constant current diode, FET, constant current means using a resistor, or the like.

Hereinafter, the present invention will be described based on specific examples.
However, the embodiments of the present invention are not limited to the following examples.

  The present invention is an example used for a television broadcasting system using an FTTH system. FIG. 1 is a circuit diagram of a high-frequency amplifier circuit 100 of the optical terminal device according to the first embodiment. The PIN photodiode 6 as a photoelectric conversion element is an element that receives an optical signal propagated through the FTTH transmission path and converts it into an electrical signal. A current multiplication transformer 7 composed of a center tap inductor is connected to the anode of the PIN photodiode 6, and the other end of the current multiplication transformer 7 is grounded. The center tap terminal of the current multiplication transformer 7 is connected to the signal input terminal a1 of the first high-frequency amplifier circuit 101.

  The first high-frequency amplifier circuit 101 is a broadband amplifier that amplifies a broadband signal such as a frequency-multiplexed television broadcast signal. The first high-frequency amplifier circuit 101 includes three amplifiers 8a, 8b, and 8c cascaded in three stages. The signal output terminal of the final-stage amplifier 8c is the signal output terminal of the first high-frequency amplifier circuit 101. This signal output terminal b1 is also connected to the signal input terminal of the directional coupler 13. The power supply terminal c1 of the first high-frequency amplifier circuit 101 is connected to the power supply terminal 18 of the high-frequency amplifier circuit 100 via a power supply line s, whereby each of the power supply units of the amplifiers 8a, 8b, 8c The terminal 18 is connected in parallel. That is, the amplifiers 8a, 8b, and 8c are all supplied with power directly from the power supply terminal 18.

  On the other hand, the second high-frequency amplifier circuit 102 receives a signal in a band (for example, a voice notification broadcast band in the FM broadcast band of 70 to 90 MHz) allocated to the voice notification broadcast among the signals received from the FTTH transmission path. Amplify. The second high-frequency amplifier circuit 102 includes a low-pass filter 10 that passes the above-described audio notification broadcast band signal and two amplifiers 11a and 11b connected in cascade. The signal output terminal of the subsequent amplifier 11b also serves as the signal output terminal b2 of the second high-frequency amplifier circuit 102. However, the low-pass filter 10 includes a buffer resistor (not shown) in the preceding stage, and the signal in the audio notification broadcast band first passes through the buffer resistor.

The signal output terminal b2 is connected to the isolation terminal 132 of the directional coupler 13 through the attenuator 12 (ATT). The attenuator 12 (ATT) functions as a termination resistor (matching resistor) of the directional coupler 13 when the amplifier 11b is not operating, and passes and branches the broadband signal output from the first high-frequency amplifier circuit 101. And the characteristic of directional coupling is made good.
The second high-frequency amplifier circuit 102 is designed to amplify a high-frequency signal in the band of 70 to 80 MHz allocated to the above-mentioned voice announcement broadcasting, and the signal input stage has a pass band of 70 to 80 MHz. An FM band passing low pass filter 10 is arranged. The high-frequency signal input to the second high-frequency amplifier circuit 102 is input to the first amplifier 11 a through the low-pass filter 10. The input terminal of the low-pass filter 10 also serves as the signal input terminal a2 of the second high-frequency amplifier circuit 102, and the signal input terminal a2 is connected to the cathode of the PIN photodiode 6.

The cathode end of the PIN photodiode 6 is connected to a power supply terminal 18 through a resistor 9, a resistor R1, a diode 15, a resistor 16 (hereinafter sometimes referred to as a current limiting resistor 16) and a voltage regulator 17 in this order in series. It is connected to the. A capacitor C ₀ is connected to a connection point m ₁ between the resistor 9 and the resistor R1, and the other end of the capacitor C ₀ is grounded. The opposite end of the resistor R1 and a connection point m _1, the resistor R1 and the diode 15 is connected to a connection point m ₂ for connecting the cathode end (hereinafter, sometimes referred to as backflow prevention diode 15) ing. One end of the large-capacitance capacitor 14 used as a backup power source during a power failure is connected to the connection point m ₂ and the other end is grounded.

The current limiting circuit 26 is a constant current source that limits the discharge current from the large-capacity capacitor 14 to a constant small value by lowering the power supply voltage to the amplifier circuit from the beginning of power supply at the time of commercial power failure. Is configured by connecting a plurality of constant current diodes in parallel. However, it may be composed of one constant current diode. The output terminal of the current limiting circuit 26 is connected to the power supply terminal c2 of the second high-frequency amplifier circuit 102 described above, the input end is connected to the connection point m _2. However, as will be described in detail later with reference to FIG. 2, the second high-frequency amplifier circuit 102 is not activated when the commercial power supply is normal due to the operation of the activation control device of FIG.
Hereinafter, the operation of the high-frequency amplifier circuit 100 will be described in detail.

Electric power supplied from an AC 100 V commercial power source is converted into DC by a converter (not shown) and is fed from the power supply terminal 18. The DC power supplied from the power supply terminal 18 when the commercial power supply is normal is supplied in parallel to the high-frequency amplifiers 8a to 8c constituting the first high-frequency amplifier circuit 101 and simultaneously to the voltage regulator 17. Is also supplied.
When the commercial power supply is normal, the large-capacitance capacitor 14 is charged from the voltage regulator 17 via the current limiting resistor 16 and the backflow prevention diode 15. Further, by connecting the backflow prevention diode 15 as described above, backflow of current from the large-capacitance capacitor 14 to the voltage regulator 17 is prevented at the time of a power failure.

The PIN photodiode 6 is reverse-biased with the output voltage of the voltage regulator 17 when the commercial power supply is normal, and reverse-biased with the terminal voltage of the large-capacitance capacitor 14 when the commercial power supply is interrupted. At the time of commercial power failure, the large-capacitance capacitor 14 feeds power to the amplifiers 11a to 11b from the power supply terminal c2 through the current limiting circuit 26 in order to operate the amplifier at the time of power failure.
When the power supply is normal, the high-frequency signal received from the FTTH transmission line by the PIN photodiode 6 and subjected to photoelectric conversion is amplified by the first high-frequency amplifier circuit 101 from the current multiplication transformer 7, and the directional coupler 13. And output to an output device such as a television receiver, an FM notification broadcasting terminal, or an FM radio.

  The branch terminal 131 of the directional coupler 13 serves as a monitor terminal for a high-frequency output signal when the power supply is normal. Further, the directional coupler 13 operates to input an FM band high-frequency signal amplified by the second high-frequency amplifier circuit 102 from the isolation terminal 132 and output it to the output terminal 133 during a power failure. . In this way, by using the directional coupler 13, it is possible to monitor a broadband television signal that is a broadcast signal when the power supply is normal, and output an FM band signal that is a signal of an audio notification broadcast band from an output terminal during a power failure. be able to.

  At the time of a commercial power failure, a high frequency signal is taken out from the cathode end of the PIN photodiode 6, and only the FM band is input from the signal input terminal a2 by the low-pass filter 10 for passing through the FM band. The operating currents of the amplifiers (11a, 11b) operated at the time of a power failure are about 0.6 mA, which is set to be significantly lower than the operating currents of 200 to 300 mA of the amplifiers (8a, 8b, 8c) operated when the commercial power supply is normal. Has been. That is, in order to amplify a low frequency narrowband signal of an audio notification broadcast of 70 to 90 MHz, a sufficient amplification factor can be obtained even with a low voltage and therefore a small current as illustrated in FIGS. The high-frequency amplifier circuit 100 according to the first embodiment pays attention to the gain characteristics of the amplifiers illustrated in these graphs, and a second high-frequency amplifier sufficient to amplify the low-frequency narrow-band signal in the voice notification broadcast band By providing the circuit 102, voice announcement broadcasting can be performed for a long time during a power failure.

FIG. 2 shows a circuit diagram of the amplifier 11a. The base terminal t _B of the transistor 21 is connected to an FM signal input terminal 22 for inputting a high-frequency signal that has passed through the low-pass filter 10 via a DC cut capacitor C ₁ . The collector terminal t _C of the transistor 21 is connected to the FM signal output terminal 23 via a DC cut capacitor C ₂ . Further, the base terminal t _B and the collector terminal t _C are connected via a resistor r2.

One end of the resistor r1 serving as the load resistance of the transistor 21 is connected to the collector terminal t _C and the other end is connected to the output terminal of the current limiting circuit 26 described above. One end of the resistor r3 is connected to the base terminal t _B, the other end is grounded.
The resistance values of the resistors r1, r2, and r3 are set so that an appropriate bias voltage is applied to the base terminal t _B during a power failure.

The greatest characteristic point of the amplifier 11a is the potential setting method at the emitter terminal t _E of the transistor 21. The emitter terminal t _E is connected to the DC output terminal of the voltage regulator 17 through the resistor 24 and is grounded through the resistor 25 at the same time. That is, the DC voltage output from the voltage regulator 17 is divided by the resistor 24 and the resistor 25 and applied to the emitter terminal t _E. High-frequency component of the emitter current of the transistor 21 is grounded through a capacitor C _3.

Hereinafter, an operation of the activation control device configured using the resistor 24 and the resistor 25 will be described.
As described above, the divided voltage generated by the resistor 24 and the resistor 25 of the DC voltage output from the voltage regulator 17 is applied to the emitter terminal t _{E. In} this state, the potential V _B of the base terminal t _B of the transistor 21 the value of resistor for each biased to a voltage difference is equal to or less than a predetermined threshold voltage (V _B -V _E <th) and the potential V _E of the emitter terminal t _E is set. Therefore, the transistor 21 does not operate while direct current is supplied from the voltage regulator 17.

On the other hand, since the DC voltage output from the voltage regulator 17 decreases during a commercial power failure, the divided voltage is not applied to the emitter terminal t _E of the transistor 21, and the potential V _E of the emitter terminal t _E drops to the ground potential. . At this time, the voltage difference between the base potential V _B and the emitter potential V _E of the transistor 21 becomes equal to or higher than the threshold voltage (V _B −V _E ≧ th), and the transistor 21 enters an operating state and exhibits a desired amplifying action. When in the operating state, V _B -V _E receives feedback from the emitter current. In this way, the second high-frequency amplifier circuit 102 can amplify the signal in the voice notification broadcast band only at the time of a power failure.

  According to the above configuration, since the power to be provided by the backup power supply device can be reduced, the voice notification broadcast can be received for a long time even when the commercial power supply is interrupted.

FIG. 3 is a circuit diagram of the high-frequency amplifier circuit 200 of the optical terminal device according to the second embodiment. The high frequency amplifier circuit 200 is different from the high frequency amplifier circuit 100 of the first embodiment in the configuration of the backup power supply. That is, in the high frequency amplifier circuit 200, a backup power source is configured using the small primary battery e and the backflow preventing diode 15b. A connection point m ₂ that connects the resistor R1 and the cathode end of the backflow prevention diode 15 is directly connected to the power supply terminal c2 of the second high-frequency amplifier circuit 202 by wiring, and a small primary battery e is placed in the middle of the wiring. Are connected via a diode 15b. However, the cathode end of the backflow prevention diode 15b is connected to the power supply terminal c2 side, and the anode end of the backflow prevention diode 15b is connected to the positive electrode side of the small primary battery e. When the power supply is normal, power is supplied from the voltage regulator 17 to the amplifier via the backflow prevention diode 15, and the cathode potential of the diode 15b is higher than the voltage of the small primary battery e so that the small primary battery e is not discharged. It is set high.

  For example, even with such a simple backup mechanism using the primary battery e, a long backup time can be secured by substantially the same operation as in the first embodiment.

In each of the above-described examples, the embodiment in which the backup capacitor (large capacity capacitor), the primary battery, or the secondary battery is included in the high-frequency amplifier circuit 100 or the high-frequency amplifier circuit 200 of the optical terminal device is illustrated. For example, in the following cases, a configuration in which such a backup power source is provided outside a desired optical terminal device is also conceivable.
(Case 1) The installation location of the optical terminal device is outdoors, and the environment such as the outdoor temperature is not desirable for the backup primary battery or secondary battery. In such a case, it is desirable to arrange at least the backup battery indoors.
(Case 2) A case where a reduction in the size of the optical terminal device casing is strongly demanded, and it is difficult to mount a sufficiently large backup power source inside the optical terminal device.

  FIG. 4 is a circuit diagram of the high-frequency amplifier circuit 300 of the optical terminal device according to the third embodiment. The high-frequency amplifier circuit 300 supports a method in which a backup power supply is provided outside a desired optical terminal device, for example, in the case described above. When the power supply is normal, a high DC voltage is applied by a converter (not shown), but at the time of a power failure, a lower DC voltage is applied by a backup power supply (primary battery or secondary battery) (not shown) than when it is normal.

  In the high-frequency amplifier circuit 300, the DC voltage at the power supply terminal 18 is detected by the comparator 20, and whether the commercial power supply is normal or not is determined based on the magnitude. Based on this determination, the power supply terminal 18 is connected via the relay 19 to the input terminal of the regulator 17 when the commercial power supply is normal, and to the anode terminal of the backflow prevention diode 15b during a power failure. By such a switching operation, the high-frequency amplifier circuit 300 becomes a circuit that is substantially equivalent to the high-frequency amplifier circuit 200 of FIG. 3, and thus provides substantially the same operations and effects as those of the second embodiment.

In addition, the high-frequency amplifier circuit 300 includes the relay 19 and the comparator 20, and thus has a feature that it can be configured with one power supply terminal 18 in spite of executing the switching operation as described above.
Further, according to such a configuration, the high-frequency amplifier circuit 300 can be further downsized than the high-frequency amplifier circuit 100 or the high-frequency amplifier circuit 200 described above.

  FIG. 5 shows a circuit diagram of the high-frequency amplifier circuit 400 of the optical terminal device according to the fourth embodiment. The high-frequency amplifier circuit 400 removes the second high-frequency amplifier circuit 102 and the attenuator 12 from the high-frequency amplifier circuit 100 of the first embodiment, and further connects the output terminal of the current limiting circuit 26 to the power supply terminal c1 of the high-frequency amplifier circuit 401. It is almost the same as the one directly connected to. However, a backflow prevention diode 15b is inserted in the middle of the power supply line s for supplying power to the power supply terminal c1 from the power supply terminal 18 in the same manner as the high-frequency amplifier circuit 300 (FIG. 4).

  This circuit is an embodiment that does not include an amplifier (second high-frequency amplifier circuit) that operates at the time of a power failure. When the power supply voltage is normal, the amplifier (high-frequency amplifier circuit 401) is operated with a standard current. The power supply voltage is reduced, and the current of the same amplifier (high frequency amplifier circuit 401) is limited to operate. The gain of the high frequency amplifier circuit 401 is lowered and backed up.

  The current limiting circuit 26 is configured by connecting a plurality of constant current diodes in parallel with the cathode terminal facing the power supply terminal c1 side, that is, the output side. However, it may be composed of one constant current diode. That is, the current limiting circuit 26 reduces the terminal current of the power supply terminal c1 and stabilizes the load current by reducing the terminal voltage even in the initial stage of the power supply backup where the terminal voltage of the large-capacitance capacitor 14 is high. It is possible to secure a long backup time.

  In addition, for example, by a power supply method employing such a power supply backup mechanism, as can be seen from the general gain characteristics (FIGS. 6 and 7) of the amplifier mentioned above, a wideband television band signal can be obtained during a power failure. Can not be amplified, but it is possible to maintain for a long time a signal in the audio notification broadcast band arranged in a band lower than the broadband television signal band.

  In addition, any of the current limiting circuits 26 of the embodiments can be configured using FETs or the like.

  According to the present invention, even if a power failure occurs when a disaster is predicted, a voice notification broadcast output from a local government or the like can be heard in each home, and this is effective for disaster prevention. It is also effective for disaster countermeasures after a disaster occurs.

Circuit diagram of the high-frequency amplifier circuit 100 of the optical terminal device according to the first embodiment. Circuit diagram of amplifier 11a of high-frequency amplifier circuit 100 Circuit diagram of the high-frequency amplifier circuit 200 of the optical terminal device according to the second embodiment. Circuit diagram of high-frequency amplifier circuit 300 of the optical terminal device according to the third embodiment. Circuit diagram of the high-frequency amplifier circuit 400 of the optical terminal device according to the fourth embodiment. Graph illustrating the gain characteristics of a typical amplifier Graph illustrating the gain characteristics of a typical amplifier

100: High frequency amplifier circuit of optical terminal device (Example 1)
200: High frequency amplifier circuit of optical terminal device (Example 2)
300: High frequency amplifier circuit of optical terminal device (Example 3)
400: High frequency amplifier circuit of optical terminal device (Example 4)
6: PIN photodiode (photoelectric element)
7: Current multiplying transformer 8a: Amplifier (normal)
9: Resistance 10: Low-pass filter (for FM band pass)

11a: Amplifier (at power failure)
12: Attenuator 13: Directional coupler 14: Large capacity capacitor 15: Diode (for backflow prevention)
16: Current limiting resistor 17: Voltage regulator 18: Power supply terminal 19: Relay 20: Comparator

21: Transistor 22: FM signal input terminal 23: FM signal output terminal 24: Switch current limiting resistor 25: Grounding resistor 26: Current limiting circuit e: Small primary battery

Claims (7)

Each of the systems in which the multiplexed broadband television signal and the narrow band audio notification broadcast signal that is lower than the bandwidth of the broadband television signal are multiplexed and distributed to each terminal through an optical transmission line An optical terminal device that is installed in a terminal, converts an optical signal into an electrical signal, amplifies it, and supplies it to an output device,
A power supply terminal for supplying DC power converted from a commercial power supply;
A photoelectric conversion element that is connected between the power supply terminal and ground and converts the optical signal into the electrical signal;
A backup power supply device connected to the photoelectric conversion element so as to supply DC power to the photoelectric conversion element when the commercial power supply fails.
A first terminal that is connected to one terminal of the photoelectric conversion element, amplifies the electric signal of the entire band converted by the photoelectric conversion element , and is connected to the power supply terminal and connected to the power supply terminal, and is supplied with power from a commercial power source and operates . A high frequency amplifier circuit of
Connected to the other terminal of the photoelectric conversion element, amplifies a narrow-band signal including the band of the audio notification broadcast signal among the electric signals converted by the photoelectric conversion element, and outputs the amplified signal to the output device, a power supply terminal Is connected to the backup power supply device and is operated by being supplied with power from the backup power supply device ;
Have
The second high-frequency amplifier circuit includes a transistor that amplifies a signal and a bias circuit, and the bias circuit applies a voltage to the base / gate of the transistor by a voltage from the backup power supply device, and the power supply By applying a voltage to the emitter / source of the transistor using the voltage from the terminal, the base / gate and emitter / source bias voltages of the transistor are set to be equal to or higher than the threshold voltage during the commercial power supply interruption. An optical terminal device characterized in that it is a circuit in which a period during which power is supplied from a power source is lower than a threshold voltage . The photoelectric conversion element is a photodiode, and an input end of a high-frequency signal of the second high-frequency amplifier circuit is connected to a cathode of the photoelectric conversion element,
The optical terminal apparatus according to claim 1, wherein an input terminal of a high-frequency signal of the first high-frequency amplifier circuit is connected to an anode of the photoelectric conversion element. The optical terminal device according to claim 1, wherein the backup power supply device is a large-capacity capacitor that is charged by power supply from a commercial power supply. The optical terminal device according to claim 3, wherein the backup power supply device includes a current limiting circuit that makes a feeding current constant to a small current with respect to the second high-frequency amplifier circuit. The input terminal for inputting the output signal of the first high frequency amplifier circuit and the isolation terminal for inputting the output signal of the second high frequency amplifier circuit, and the branch terminal is a monitor terminal for the broadband television signal. optical terminal device according to any one of claims 1 to 4, characterized in that it has a directional coupler. Light terminal according to any one of claims 1 to 5, further comprising a filter for passing narrowband signal including the voice announcement broadcast band in the input stage of the second high-frequency amplifier circuit apparatus. Each of the systems in which the multiplexed broadband television signal and the narrow band audio notification broadcast signal that is lower than the bandwidth of the broadband television signal are multiplexed and distributed to each terminal through an optical transmission line An optical terminal device that is installed in a terminal, converts an optical signal into an electric signal, amplifies it, and supplies it to an output device.
A power supply terminal for supplying DC power converted from a commercial power supply;
A photoelectric conversion element that is connected between the power supply terminal and ground and converts the optical signal into the electrical signal;
A backup power supply device connected to the photoelectric conversion element so as to supply DC power to the photoelectric conversion element when the commercial power supply fails.
A high-frequency amplifier that is connected to one terminal of the photoelectric conversion element, amplifies the electrical signal of the entire band converted by the photoelectric conversion element, and that is connected to the power supply terminal and connected to the power supply terminal and is supplied with power from a commercial power supply. Circuit,
A current limiting circuit including a constant current diode connected between the backup power supply device and the power supply terminal of the high-frequency amplifier circuit and supplying a constant current from the backup power supply device to the high-frequency amplifier circuit;
An optical terminal device comprising: